Container and blade arrangement for food preparation appliance

ABSTRACT

In a container and method for processing food, the container has a closed end, and open end and a tubular sidewall extending therebetween and together with the closed end defining an interior space of the container. The container is configured to accommodate a blade member within the interior space of the container. The container has a center and the sidewall has at least one rib projecting inward of the interior space of the container and extending heightwise along at least a portion of the sidewall. The rib is asymmetric in transverse cross-section. A blade member is also disclosed and is configured to have different planes in which the blade member moves upon rotation of the blade.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to U.S. Provisional Patent Application Ser. No. 61/782,879, filed on Mar. 14, 2013, which is incorporated in its entirety herein.

FIELD

The field of the disclosure relates generally to food preparation appliances, and more particularly to food preparation appliances such as blenders and food processors that operate one or more blades within a container to process food disposed within the container.

BACKGROUND

Food preparation appliances such as blenders and food processors are commonly use to process foods, such as by chopping, crushing, cutting, liquefying, blending, mixing, etc. Such appliances typically have a container in which the food is loaded for processing. The container has one or more blades disposed within the container and sits on a base that houses a drive motor that upon seating of the container on the base is drivingly connected to the one or more blades in the container. A lid is typically placed on the top of the container to close the container during operation of the appliance.

In some blenders and food processors, the contents in the container tend to rotate about the inner volume of the container during processing. However, the contents are not always evenly mixed. Often times, for example, the contents nearest the blades may be liquefied, whereas contents located further from the blades remain intact (e.g., chunky). In order to improve the performance (i.e., improve the homogeneity of the mixed contents), at least some known containers include a series of ribs extending vertically along all or a portion of the inner sidewall of the container. These ribs may have varying sizes and shapes in cross-section, or contour as taken along the inner circumference of the container, but tend to have a symmetric incline and decline section along the circumferential contour of the inner sidewall of the container. The purpose of the ribs is to create turbulence in the contents of the container as they rotate within the container.

When the contents rotate along the inner circumference of the container sidewall, they strike the ribs and will either travel upward (e.g., vertically) along the inclined side of the rib or travel circumferentially over the rib to its declined side. The contents that travel over the rib may enter a stagnant flow region on the declined side of the rib, and in some instances the contents can remain in the stagnant region for substantially the entire duration of operation of the appliance. As such, the contents in the stagnant zone are not well processed, and the final mixture is not homogeneous. Thus, the ribs may reduce the performance and the uniformity of the final mixture contents of the blender.

The one or more blades of the appliance may also be shaped so as to impart both a rotational force and an axial force to the contents of the container during operation. For example, some blades are upwardly or downwardly angled to force the contents upward/downward as the blades strike the contents (e.g., the food), causing axial flow of the contents within the container. However, performance of the blades can vary with the speed at which the blades are rotated and the contents that are being mixed. In some instances, for example, excessive blade rotation speeds may induce cavitation within the contents being processed, or cause the contents to be forced upward and out of the top of the container. Cavitation within the contents may also cause non-uniformity in the final mixture and thus reduce the efficiency and usefulness of the appliance.

As such, a need exists for a food preparation appliance that provides improved efficiency and uniformity of the processed contents.

BRIEF DESCRIPTION OF THE INVENTION

In one aspect, a container for a food preparation appliance that includes a blade member rotatable relative to the container in a direction of rotation generally comprises a closed end and an open end. A tubular sidewall extends from the closed end to the open end and together with the closed end defines an interior space of the container. The container is configured to accommodate the blade member within the interior space of the container. The sidewall has a rim at the open end through which contents to be processed by the appliance are loaded into the interior space of the container, and the container has a center. The sidewall has a rib projecting inward of the interior space of the container and extending heightwise along at least a portion of the sidewall intermediate the open end and closed end of the container. The rib has, in the direction of rotation of the blade member, a peak defined as the shortest transverse dimension measured from the center of the container to the sidewall at a respective height along the portion of the sidewall having the rib, with the rib being asymmetric in transverse cross-section.

In one aspect of a method for processing food in a food preparation appliance, the appliance has a container and a blade member rotatably driven within the container during operation of the appliance, and the container has a sidewall including an inner surface in part defining the interior space of the container in which food is processed. The method generally comprises loading food to be processed into the interior space of the container, and operating the blade member in a direction of rotation to generate a vortex flow of the food within the container in the direction of rotation of the blade member such that at least a portion of the flow of food flows circumferentially along the inner surface of the container sidewall. The portion of the flow of food flowing circumferentially along the inner surface of the container in the direction of rotation of the blade member is directed to impact a first rapidly inclining slope of the inner surface of the container sidewall and to then flow past a gradually declining slope of the container sidewall.

In another aspect, a blade member for a food preparation appliance having a drive motor for operative connection with the blade member to drive rotation of the blade member about an axis of rotation of the blade member generally comprises a central planar portion extending substantially perpendicular to an axis of rotation of the blade member to lie in a first plane. The central planar portion has a first lengthwise end and a second lengthwise end opposite the first lengthwise end with the rotation axis of the blade member disposed therebetween. A first wing has a proximal end coupled to the first end of the central planar portion and a distal end disposed lengthwise outward of the proximal end of the first wing. A second wing has a proximal end coupled to the second lengthwise end of the central planar portion and a distal end disposed lengthwise outward of the proximal end of the second wing. At least a portion of one of the first wing and the second wing lies in a second plane different from the first plane of the central planar portion. An upturned wingtip extend generally upward from the distal end of one of the first wing and the second wing and a downturned wingtip extends generally downward from the distal end of the other one of the first wing and the second wing.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic side elevation of one embodiment of a food preparation appliance illustrated in the form of a blender.

FIG. 2 is a side elevation of one embodiment of a container for use with the blender of FIG. 1, with a handle omitted from the container.

FIG. 3 is a top plan view of the container of FIG. 2.

FIG. 4 is a transverse cross-section taken midway along the height of the container of FIG. 3.

FIG. 5 is a perspective view of one embodiment of a blade mount and blade member for use with the blender of FIG. 1.

FIG. 6 is a perspective view of the blade member of FIG. 5.

FIG. 7 is a top plan view of the blade member of FIG. 5.

FIG. 8 is a front elevation thereof.

FIGS. 9 and 10 are right and left side elevations, respectively, of the blade member of FIG. 8.

FIG. 11 is a perspective view of one alternative embodiment of a blade member.

FIG. 12 is a front elevation of the blade member of FIG. 11.

FIG. 13 is a top plan of one alternative embodiment of a container for use with the blender of FIG. 1.

FIG. 14 is a transverse cross-section taken midway along the height of the container of FIG. 13.

FIG. 15 is a perspective of one alternative embodiment of a blade mount.

FIG. 16 is a side elevation thereof.

FIG. 17 is a side elevation of an alternative embodiment of a container with which the blade mount of FIGS. 15 and 16 is used.

Corresponding reference characters indicate corresponding parts throughout the several views of the drawings.

DETAILED DESCRIPTION OF THE INVENTION

Referring now to the drawings, and more particularly to FIG. 1, one embodiment of a food preparation appliance is indicated generally at 100 and is illustrated in the form of a blender. The blender 100 generally includes a base 102 housing a drive motor (not shown) therein, a container 104 releasably positionable on the base and having a blade mount 500 in operative connection with the drive motor and having a blade member 502 thereon, and a lid 105 for closing the container. As used herein, direction and/or orientation terms such as lower, upper, bottom and top refer to the upright orientation of the appliance 100 as illustrated in FIG. 1. The term transverse refers to a direction normal to the height of the container, e.g., horizontal in the illustrated embodiment of FIG. 1. While in the illustrated embodiment the appliance 100 is in the form of a blender, it is understood that the appliance may be in the form of a food processor or other suitable appliance in which a blade member operates within a container to process food or other contents in the container.

With reference to FIGS. 1-3, the container 104 has a bottom 106 (FIGS. 2 and 3), and a circumferential sidewall 108 extending up from the bottom 106 of the container so that the bottom and sidewall together define an interior space (broadly, a processing chamber) 114 of the container. The sidewall 108 terminates at an upper rim 112 to define an opening 110 at the top of the container 104 through which food or other contents to be processed are loaded into the interior space 114 of the container. As seen best in FIG. 3, the bottom 106 of the container 104 has a central opening 116 therethrough to permit operative connection between the blade mount 500 and the drive motor disposed in the base 102 of the blender 100 as discussed in further detail later herein. Although the central opening 116 is illustrated as being generally circular, it is understood that the opening may be any suitable shape that allows the blender 100 to function as described herein.

In some embodiments, the container 104 may include a handle (not shown) for use in gripping and manipulating the container. The container 104 may also have a spout 118 (FIG. 3) formed generally at its upper rim 112 to facilitate pouring out the contents of the container after processing. In the illustrated embodiment of FIG. 2, the sidewall 108 of the container 104 tapers outward in cross-sectional dimension from the bottom to the top of the sidewall, such that a cross-sectional dimension W2 measured across the container at the rim 112 thereof is greater than a cross-sectional dimension W1 measured across the container where the sidewall transitions to the bottom 106. Such taper may improve blending of the contents therein, and also improves the ease of manufacturing the container 104. As also seen in FIGS. 3 and 4, at the upper rim 112 of the container 104, the container is generally circular (the spout 118 not withstanding), while the cross-section of the container is more triangular as the container sidewall 108 extends down toward the bottom 106 in accordance with the rib configurations described in further detail below. It is understood, however, that the container 104 may be of uniform cross-section along the height of the sidewall 108, or may have a non-uniform cross-sectional dimension other than as illustrated in FIGS. 2 and 3, without departing from the scope of this invention. The container 104 may be constructed of any suitable material including, without limitation, plastic, glass, metal, metal alloys, composites and combinations thereof.

With reference to FIGS. 2 and 3, the blade member 502 is rotatable relative to the container 104 in a rotational direction R as indicated by the direction arrow in FIGS. 3 and 4. In the illustrated embodiment, the container 104 has three rib sections 202, 204 and 206, each extending vertically along a segment of the height of the container sidewall 108 generally from adjacent the bottom 106 of the container to a height less than the full height of the container such that the inner surface, or inner circumference of the sidewall is contoured along a vertical segment of the container. More particularly, with reference to a trace taken along the contoured inner circumference of the sidewall 108 in the direction of rotation R, each rib 202, 204, 206 has a respective peak 218 (for rib 202), 217 (for rib 204) and 212 (for rib 206). With reference to rib 202, each rib includes a respective inflow segment 210 that widens in transverse dimension (e.g., in radius) along the rotational direction R leading into a respective base 214 of the rib 202. The rib peak 218 (e.g., of rib 202) is defined by the point along the rib having the smallest transverse dimension (e.g., radius) measured from a center C of the container 104 to the rib peak 218. The base 214 (e.g., of rib 202) is defined by the point along the rib having the largest transverse dimension measured from the center C to the rib base 214.

The rib 202 further includes a step 216 that decreases in transverse dimension (e.g., in radius) along the direction of rotation R from the rib base 214 to the rib peak 218 of the rib 202. In the illustrated embodiment, the base 214 where the inflow segment 210 transitions to the step segment 216 is generally in the form of a fillet 220 (e.g., rounded) to create a smooth transition therebetween to thereby improve the flow characteristics of the container contents being processed. In other embodiments, however, the base 214 may be configured other than as a fillet, and may even define a straight corner, within the scope of this invention. The rib 202 also has an outflow segment 222 extending away from the peak 218 and along which the transverse dimension (e.g., radius) increases along the direction of rotation R. The outflow segment 222 transitions into the inflow segment 210 of the next rib 204 along the direction of rotation R. In this manner, for each rib (e.g., using rib 202 as an example), the inflow segment 210, step 216, peak 218 and outflow segment 222 together define a generally S-shaped contour, which creates a smooth transition between adjacent ribs 202, 204, 206.

The inflow segment 210 creates a gradual transversely (e.g., radially) outward slope along the direction of rotation R, whereas the step 216 has a relatively steep transversely inward slope to the peak 218 of the rib 202. In some embodiments an angular distance α from the rib base 214 to the rib peak 218 is approximately one-third of an angular distance β between circumferentially adjacent rib peaks (e.g., 217, 218). As one example, in the embodiment of FIG. 3 the angular distance β between circumferentially adjacent rib peaks 217, 218 is about 120 degrees, such that the angular distance α from the rib base 214 to the rib peak 218 is less than about 40 degrees, and in the illustrated embodiment less than about 30 degrees. Additionally, at any given transverse cross-section of the container 104 along which the ribs 202, 204, 206 extend, a radial distance R_(P) from the center C of the container 104 to the peak 218 of the rib 202 is between about 60% to about 95% of a radial distance R_(B) from the center C of the container to the base 214 of the same rib 202.

With reference still to FIGS. 2 and 3, in the illustrated embodiment the container 104 further includes inclined ramp sections 300 (one associated with each rib 202, 204, 206) disposed axially (e.g. heightwise in the illustrated embodiment) between the bottom 106 of the container and the sidewall 108 thereof and circumferentially along the base 214, step 216 and peak 218 of each respective rib (e.g., rib 202). Each ramp section 300 increases in height as it extends circumferentially in the direction of rotation R from the inflow segment 210 to the step 216 of the rib 202. The height of the ramp section 300 also generally increases in height as it extends radially outward from the center of the container. As such, the height of the ramp section 300 is greater adjacent the base 214 and step 216 of the rib 202 than at the outflow segment 222 and inflow segment 210 of the rib.

With reference now to FIG. 5, the blade mount 500 comprises a hub 504 and an externally threaded cylindrical column 506 depending from the hub such that the column extends down through the central opening 116 of the bottom 106 of the container 104 (see, e.g., FIG. 1) whereby the hub sealingly seats down against the inner surface of the bottom of the container. The illustrated hub includes a sealing gasket 508 to facilitate sealing engagement of the hub against the bottom 106 of the container 104. A nut 510 or other suitable fastener is mounted on the threaded column below the bottom 106 of the container 104 for use in tightly securing the hub 504 on the bottom of the container. A drive shaft 606 extends through the 506 column for operative connection at one (i.e., upper) end to the blade member 502 and at an opposite (i.e., lower) end to a drive coupling 600 that operatively couples with the drive motor (not shown) in the base 102 of the blender 100. The blade mount further includes an annular support plate 604 adjacent the upper end of the drive shaft 606.

With general reference to FIGS. 6-10, and in particular referring first to FIG. 6, the blade member 502 includes a central hub 700 having an opening 702 therein keyed to the cross-sectional configuration of the upper end of the drive shaft 606 of the blade mount 500 to thereby operatively connect the blade member 502 to the drive motor for driven rotation of the blade member relative to the container 104 upon operation of the drive motor. In some embodiments, the hub 700 and opening 702 of the blade member 502 may be configured relative to the drive shaft 606 such that the blade member 502 may only be installed on the blade mount 500 in a single orientation (i.e., such that the blade member cannot be installed upside down). The blade member 502 may be releasably or permanently connected to the blade mount 500 within the scope of this invention. The blade member 502 may be made of a metal, metal alloy, plastic, ceramic, composite or any other suitable materials and combinations thereof that allow the blade member 502 to function as described herein. In one suitable embodiment, for example, the blade member 502 is constructed of stainless steel.

The blade member 502 has a planar portion 704 (including at least part of the blade member hub 700) extending substantially perpendicular to an axis of rotation A_(R) (FIG. 8) of the blade member. A first wing 706 extends transversely outward from the planar portion 704 and has a proximal end 708 coupled to the planar portion 704 and a distal end 710 outward of the proximal end. A second wing 712 extends transversely outward from the planar portion 704 on a side of the hub 700 opposite the first wing 706. The second wing 712 has a proximal end 714 coupled to the planar portion 704 and a distal end 716 outward of the proximal end 714 of the second wing 712. An upturned wingtip 718 extends upward from the distal end 710 of the first wing 706 and a downturned wingtip 720 extends downward from the distal end 716 of the second wing 712. The first wingtip 718 and the second wingtip 720, according to one embodiment, are bent at a bend radius of between about 1 millimeter to about 5 millimeters. Each of the first wing 706 and the second wing 712 has a respective leading edge 722, 724 and a respective trailing edge 726, 728. Each of the leading edges 722, 724 may be shaped to have a knife edge (i.e., an angled edge) to facilitate cutting of the contents to be processed in the container 104 when in use. In the illustrated embodiment, the planar portion 704 has opposite blunt, or squared, outer edges 730, 732, although these edges may be partially or wholly sharpened to a knife edge to improve ease of manufacturing the blade member.

Similarly, the first wingtip 718 and the second wingtip 720 may include an angled knife edge 734, 736 to further facilitate cutting or chopping of the contents of the container 104 in use. As seen best in FIGS. 9 and 10, the wingtips 718, 720 are generally rectangular in shape (e.g., in profile as viewed from the longitudinal ends). In other embodiments, however, one or both of the wingtips 718, 720 may be other than rectangular in profile and remain within the scope of this invention. For example, the leading edge 734, 736 of either one or both of the wingtips 718, 720 may be curved, e.g., rounded. The upper edges of the wingtips 718, 720 may also be rounded such that the leading edges 734, 736 and upper edges together form a single continuous knife edge that arcs from the leading edge 722, 724 of the wing 706, 712 to the trailing edge 726, 728.

As best illustrated in FIGS. 8-10, the planar portion 704, the first wing 706, and the second wing 712 each extend along a respective different plane such that the blade member 502 has a generally twisted appearance. The planar portion 704 is substantially perpendicular to the axis of rotation A_(R), which facilitates secure coupling of the blade member 502 to the blade mount 500. More particularly, the planar portion 704 sits flat against the support plate 604 of the blade mount 500. In the illustrated embodiment, the first wing 706 is twisted, such that the leading edge 722 is higher than the trailing edge 726. The second wing 712 is also twisted such that its leading edge 724 is above its trailing edge 728. In one example, each of the first wing 706 and the second wing 712 may be twisted to an angle α_(T) of between about 0.1 degrees to about 15 degrees with respect to the planar portion 704. As such, when the blade member 502 is rotated in the first direction R (FIG. 7), a propeller action is created, which forces contents in the container 104 that are contacted by the blade member in a downward direction toward the bottom 106 of the container. It should be understood that a lower twist angle reduces strain on the drive mechanism, but reduces the propeller action of the blade member 502, while increased twist angles increase the strain on the drive mechanism but also increase the propeller action of the blade member in use. In other embodiments, one or both of the first and second wings 706, 712 may not be twisted and remain within the scope of this invention.

Each of the first wing 706 and the second wing 712 has a radial length L₁, L₂ (FIG. 8) respectively measured from the axis of rotation A_(R) of the blade member 502 to a center of the respective wingtip 718, 720. In the illustrated embodiment, L₂ is greater than L₁ such that the second wingtip 720 will pass closer to the upstanding sidewall 104 of the container than the first wingtip 718 during operation. However, in other embodiments, L₁ may be greater than L₂, or L₁ and L₂ may be equal without departing from the scope of this invention.

Referring to FIGS. 6 and 8, the first wingtip 718 is bent upward from the first wing 706 at an angle that is between 70 degrees and 110 degrees relative to the planar portion 704 of the blade member 502. The second wingtip 720 is bent downward with respect to the second wing 728 at a downward angle less than 90 degrees relative to the planar portion 704. However, the second wingtip 720 may be bent at any angle 90 degrees or less that allows the blade member 502 to function as described herein. In some embodiments, for example, the second wingtip 720 may be bent downward at an angle in the range of approximately 45 degrees to approximately 70 degrees with respect to the planar portion 704 of the blade member 502 to ease in the manufacturing of the blade member, or provide an alternate direction of movement of the contents being processed that is better suited for alternate container 104 geometries. As illustrated best in FIGS. 9 and 10, the wingtip 718 is configured such that the highest point of the leading edge 734 is the highest point of the blade member 502. This ensures that as the blade member 502 rotates, the highest point of the leading edge 734 of the first wingtip 218 comes into contact first with larger objects or chunks (e.g., ice) that are sucked downward in the blender 100 toward the blade member. The leading edge 736 may be higher or lower than the trailing edge of the second wingtip without departing from the scope of this invention.

With reference back to FIG. 7, the first (e.g., upturned) wingtip 718 of the illustrated embodiment is suitably angled relative to the generally straight leading edge 722 of the first wing 706 an angle θ_(T) in the range of about 50 degrees to 90 degrees. This further facilitates the leading edge 734 of the upturned first wingtip to come into contact with chunks (e.g., ice) in the middle (heightwise) region of the blender during use, thus minimizing the chances that large chunks will be left in the blender after processing. The second (downturned) wingtip 720 is suitably angled relative to the generally straight leading edge 724 of the second wing 712 an angle θ_(B) of less than 90 degrees, and more suitable less than 85 degrees. In this manner, as the blade rotates, the outer face of this wingtip 720 sweeps through the contents of the blender and pushes it radially outward, thus causing the material to get pushed into the sidewall 108 of the container for recirculation and chopping by the first wingtip 718. This also helps circulation of the contents from the region surrounding the blade member 502, up the sidewall 108 and back down the center of the vortex as described further below.

It should be noted that the hub 504 of the blade mount 500 has a height (e.g., above the bottom 106 of the container 104) sufficient that the second wingtip 720 does not make contact with the bottom of the container when in use. In operation, as the blade member 502 is rotated in the first direction R (FIG. 7), the first wingtip 718 may contact and break-apart large chunks of material in the container 104, e.g., before the material is drawn downwardly toward the first wing 706 and the second wing 712 by the propeller action of the blade member 502. The leading edges 722 and 724 then strike the material and further break apart the material. The material is then further propelled downward, where the second wingtip 720 then contacts the material. While in the illustrated embodiment the blade member 502 has two wings 706, 708, it is understood that the blade member 502 may have a single wing, or it may have more than two wings, such as four wings, without departing from the scope of this invention.

Operation of the blender 100 will now be described. The container 104, with the blade member 502 and blade mount 500 assembled therewith, is placed on the blender base 102 as illustrated in FIG. 1. The drive coupling 600 of the blade mount 500 operatively connects to the drive motor (not shown) housed in the base 102 of the blender 100 such that the drive motor imparts a rotation to the drive coupling 600, and thus the blade member 502, upon operation of the drive motor. A user then loads the container 104 (with the lid 105 removed) with one or more materials (e.g., food or other contents to be processed). The lid 105 is then placed on the container 104 to close the interior space 114 of the container so as to inhibit spills or to otherwise inhibit the contents of the container from flowing out of the container during use. The blender 100 is then activated (e.g., by switch 107 illustrated in FIG. 1) to operate the drive motor—thereby rotating the blade member 502 relative to the container 104.

As the blade member 502 rotates, the blade member contacts the contents of the container 100, as discussed above. That is, the first wingtip 718 contacts the material, and the material is subsequently propelled downward and struck by the leading edges 722, 724 before it is again struck by the second wingtip 720. Due to the rotation of the blade member 502, the contents in the container 104 move in a downward direction as well as circularly in the direction of rotation R (FIGS. 3 and 7) of the blade member. As such, a “vortex” may be generated in the contents above the blade member 502. Thereupon, the propeller action of the blade member 502 continues to propel the contents downward toward the bottom 106 of the container 104 as well as radially outward toward the sidewall 108. At least some of the contents flows outward and makes contact with the ramp sections 300 of the container 104, which function to further propel the contents back up toward the top of the container.

As the contents flow in the vortex (e.g., circular) motion within the container 104, the contents being processed flow outward toward the sidewall 108 due to centrifugal force as well as by being pushed outward by the wingtips 718, 720. With reference to FIGS. 2 and 3, the contents being processed thus flow generally circumferentially along the contour of the inner surface of the sidewall 108. In this manner, the contents flow circumferentially along the inflow segment 210 of a particular rib (e.g., rib 202) to the base 214 and then the step 216, wherein the contents are then directed transversely (e.g., radially) inward toward the center C of the container 104. At this point, the contents meet another abrupt change in direction of the rib at the rib peak 218, wherein the rib transitions to the outflow segment at which the transverse dimension begins to gradually increase into the inflow segment of the circumferentially next rib 204.

Without being bound to a particular theory, it is believed that the rapid change in direction caused by the contents flowing from the step 216 to the peak 218 creates turbulence in the vortex flow of the contents, and facilitates the contents moving in an upward direction along the sidewall 108 at or near the rib step 216 and peak 218. The relatively gradual, transversely outward slope of the outflow segment 222 and inflow segment 210 provides a smooth transition from the peak of one rib to the base of the adjacent rib, which inhibits stagnant flow and ensures the material continues moving along the sidewall 108 in the direction of rotation of the blade member 502. Further, the gradual increase in the transverse cross-sectional dimension of the sidewall 108 along its height from the bottom 106 to the upper rim 112 also facilitates the continuous flow of the contents. As the contents being processed flow to a higher level within the container 104, the vortex motion of the contents caused by the propeller action of the blade member 502 again directs the material back downward toward the blade member wherein the flow path of the contents is generally repeated until the blender 100 is turned off.

FIGS. 11 and 12 illustrate one embodiment of an alternative blade member 1502 having a hub 1700, opening 1702 and planar portion 1704 similar to the embodiment of FIGS. 6-10. The blade member 1502 has a first wing 1706 and wingtip 1718 similar to the first wing 706 and wingtip 718 of the blade member 502 of FIGS. 6-10, with the exception that the first wing 1706 of this embodiment is not twisted. The blade member 1502 of this embodiment has a second wing 1720 that is also not twisted, and a downturned wingtip 1720. The second wingtip 1720 has a leading edge 1736 with a rounded transition 1744 that continues to a tip 1742 at the trailing edge 1738 of the wingtip. The second wingtip 1720 of this alternate embodiment directs contents contacted by the second wingtip in a radially outward direction, similar to the second wingtip 720 of the blade member 502. However, the second wingtip 1720 of this embodiment directs contents being processed in a more upward direction upon initial contact with the blade member and thus relies less on the configuration of the container 104 to circulate contents upward from the bottom of the container.

FIGS. 13 and 14 illustrate one alternative embodiment of a container 1104 suitable for use with the blender 100 of FIG. 1. The container 1104 has a bottom 1106, upper rim 1112, ribs 1202, 1204, 1206 and ramps 1300 similar to the container 104 of FIGS. 3 and 4. In this embodiment, however, the ribs 1202, 1204, 1206 (with rib 1202 used as an example) include a step 1216 having a substantially steeper slope than the ribs 202, 204, 206 of the container 104 of FIGS. 3 and 4. As seen in FIG. 13, while the ribs generally fade into the sidewall 1108 toward the upper rim of the container 1104, the upper rim 1112 of the container is relatively more triangular than circular as in the previous embodiment.

FIGS. 15-17 illustrate one alternative embodiment of a blade mount 2500 and container 2104 in which the blade mount is capable of removable assembly with the container by inserting the blade mount and corresponding blade member 2502 thereon up through the opening (not shown) in the bottom of the container. The blade mount 2502 comprises a housing 2512 including an annular flange 2514 extending transversely outward from the housing generally at its lower end for seating against the bottom of the container 2104 (see, e.g., FIG. 17) about the central opening therein. As illustrated best in FIG. 16, a suitable drive coupling 2600 extends axially outward from the bottom of the housing 2512 for operative connection with the drive motor of the blender. The blade member 2502 is operatively connected to the drive coupling 2600 in the same manner as blade member 502 of the embodiment of FIG. 5. The blade member 2502 may be configured similar to any of the blade members 502, 1502 described previously herein.

As illustrated in FIG. 17, the container 2104 has a downward extending collar 2120 defining the opening in the bottom of the container. The container 2104 may otherwise be configured in accordance with any of the containers 104, 1104 described previously herein. The opening at the collar 2120 is sized such that the blade member 2502 and blade mount housing 2512 are insertable upward through the opening until the annular flange 2514 of the blade mount seats up against the bottom of the collar 2120. A suitable sealing gasket (not shown) may be used between the flange 2514 and the bottom of the collar 2120 to provide sealing engagement of the blade mount 2502 to the container 2504. While not shown in the illustrate embodiment, the collar is externally threaded so that a suitable lock nut (not shown) can be used to removably retain the blade mount 2502 on the container 2504.

This written description uses examples to disclose the embodiments, including the best mode, and also to enable any person skilled in the art to practice the embodiments, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the disclosure is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims. 

What is claimed is:
 1. A method for processing food in a food preparation appliance, the appliance having a container and a blade member rotatably driven within the container during operation of the appliance, the container having a sidewall including an inner surface in part defining the interior space of the container in which food is processed, the method comprising: loading food to be processed into the interior space of the container; operating the blade member in a direction of rotation to generate a vortex flow of the food within the container in the direction of rotation of the blade member such that at least a portion of the flow of food flows circumferentially along the inner surface of the container sidewall; and directing the portion of the flow of food flowing circumferentially along the inner surface of the container in the direction of rotation of the blade member to impact a first rapidly inclining slope of the inner surface of the container sidewall, to then flow past a gradually declining slope of the container sidewall, and to then flow directly from the gradually declining slope to impact a second rapidly inclining slope of the inner surface of the container sidewall.
 2. The method set forth in claim 1 wherein the container sidewall has a circumference, the directing step being conducted a plurality of instances as the flow of food flows once about the entire circumference of the container sidewall.
 3. The method set forth in claim 1 further comprising directing the portion of the flow of food flowing along the inner surface of the container to also flow upward within the container. 